Effects of pH, stirring rate, reaction time and sequential ultrafiltration of whey protein solution on recovery and purification of glycomacropeptides

Glycomacropeptide: A comprehensive understanding of its major biological characteristics and purification methodologies

Glycomacropeptide (GMP) is a bioactive peptide derived from whey protein, consisting of 64 amino acids. It is a phenylalanine-free peptide, making it a beneficial dietary option for individuals dealing with phenylketonuria (PKU). PKU is an inherited metabolic disorder characterized by high levels of phenylalanine in the bloodstream, resulting from a deficiency of phenylalanine dehydrogenase in affected individuals. Consequently, patients with PKU require lifelong adherence to a low-phenylalanine diet, wherein a significant portion of their protein intake is typically sourced from a phenylalanine-free amino acid formula. GMP has several nutritional values, numerous bioactivity properties, and therapeutic effects in various inflammatory disorders. Despite all these features, the purification of GMP is an imperative requirement; however, there are no unique methods for achieving this goal. Traditionally, several methods have been used for GMP purification, such as thermal or acid treatment, alcoholic precipitation, ultrafiltration (UF), gel filtration, and membrane separation techniques. However, these methods have poor specificity, and the presence of large amounts of impurities can interfere with the analysis of GMP. More efficient and highly specific GMP purification methods need to be developed. In this review, we have highlighted and summarized the current research progress on the major biological features and purification methodologies associated with GMP, as well as providing an extensive overview of the recent developments in using charged UF membranes for GMP purification and the influential factors.

Application of electro-spraying technique and mathematical modelling for nanoencapsulation of curcumin

Electro-spraying Process (ESP) was used to coat extracted curcumin (CUR) with milk protein isolate (MPI) at equal concentration. The variables were applied voltage (AV), pumps flow rate ratio (PFRR) for coating (CUR with MPI), travelling distance (TD for coating and dehydration), ESE and MPI concentrations. They changed respectively from 7.5 to 27.5 kV, 2-10 times, and 5-25 cm, and 1.5-3.5% (w/w). When the MPI concentration, TD, PFRR, and AV of ESE reached respectively to 2.56 %, 16.64 cm, 6.77 times, and 19.06 kV; the resulting nanoparticle diameter and encapsulation efficiency of CUR coated (with MPI) became 232 nm (minimum) and 80.7% (maximum) values. The scanning electron microscopy (SEM) and Fourier-transform infrared spectroscopy (FTIR) analysis confirmed that the produced nanoparticles were bead-free, homogeneous, smooth surfaces, and >50% uniformity. While the nanoparticles of CUR had >70% heat resistance (up to 10 min at 120 °C against degradation), it had more than 100% antioxidant capacity in aqueous solution than its free form (because of its appropriate and intact coating). In-vitro studies showed that the nano encapsulated particles released >80% of CUR into the intestinal tract without significant release in simulated gastric fluid.